Physiologic and pathologic functions of the NPP nucleotide pyrophosphatase/phosphodiesterase family focusing on NPP1 in calcification

The catabolism of ATP and other nucleotides participates partly in the important function of nucleotide salvage by activated cells and also in removal or de novo generation of compounds including ATP, ADP, and adenosine that stimulate purinergic signaling. Seven nucleotide pyrophosphatase/phosphodiesterase NPP family members have been identified to date. These isoenzymes, related by up conservation of catalytic domains and certain other modular domains, exert generally non-redundant functions via distinctions in substrates and/or cellular localization. But they share the capacity to hydrolyze phosphodiester or pyrophosphate bonds, though generally acting on distinct substrates that include nucleoside triphosphates, lysophospholipids and choline phosphate esters. PP_i generation from nucleoside triphosphates, catalyzed by NPP1 in tissues including cartilage, bone, and artery media smooth muscle cells, supports normal tissue extracellular PP_i levels. Balance in PP_i generation relative to PP_i degradation by pyrophosphatases holds extracellular PP_i levels in check. Moreover, physiologic levels of extracellular PP_i suppress hydroxyapatite crystal growth, but concurrently providing a reservoir for generation of pro-mineralizing P_i. Extracellular PP_i levels must be supported by cells in mineralization-competent tissues to prevent pathologic calcification. This support mechanism becomes dysregulated in aging cartilage, where extracellular PP_i excess, mediated in part by upregulated NPP1 expression stimulates calcification. PP_i generated by NPP1modulates not only hydroxyapatite crystal growth but also chondrogenesis and expression of the mineralization regulator osteopontin. This review pays particular attention to the role of NPP1-catalyzed PP_i generation in the pathogenesis of certain disorders associated with pathologic calcification.     

Acetate kinase (pyrophosphate). A fourth pyrophosphate-dependent kinase from Entamoeba histolytica.

An enzyme from Entamoeba histolytica catalyzes the formation of acetyl phosphate and orthophosphate from acetate and inorganic pyrophosphate (PP_i), but it displays much greater activity in the direction of acetate formation. It has been purified 40-fold and separated from interfering enzyme activities by chromatography. Its reaction products have been quantitatively established. ATP cannot replace PP_i as phosphoryl donor in the direction of acetyl phosphate formation nor will any common nucleoside diphosphate replace orthophosphate as phosphoryl acceptor in the direction of acetate formation. The trivial name proposed for the new enzyme is acetate kinase (PP_i).     

Colorimetric determination of inorganic pyrophosphate by a manual or automated method.

A microprocedure for the colorimetric determination of inorganic pyrophosphate (PP_i) in the presence or absence of orthophosphate (P_i) has been developed. PP_i is estimated quantitatively as the amount of chromophore formed with molybdate reagent, 1-amino-2-naphthol-4-sulfonic acid in bisulfite and thiol reagent (monothioglycerol or 2-mercaptoethanol). The latter is obligatory for color formation. P_i is estimated without thiol reagent. The two chromophores differ in absorption spectra, the greatest difference being at 580 nm. For both, color develops fully by 10 min and is stable up to 1 hr. Just less than 0.4 μm PP_i can be detemined. The extinction coefficients are 2.70 × 10⁴ and 8.76 × 10³ for PP_i and P_i, respectively, both with thiol reagent present, and 2.77 × 10³ for P_i with no thiol reagent.A ten-fold excess of P_i does not interfere with the determination of PP_i and in fact can be estimated in the same mixture. A 15-fold excess, however, diminishes the accuracy of PP_i estimations. Trichloroacetic acid and sodium fluoride inhibi color formation, but this inhibition is overcome by the addition of sodium acetate buffer, pH 4.0. Nucleoside triphosphates and adenosine 3′:5′-cyclic monophosphate are stable in the reaction mixture.The method was tested in assays of Escherichia coli DNA-dependent RNA polymerase (nucleoside triphosphate: RNA nucleotidyltransferase, EC 2.7.7.6). Progress curves measured by either the rate of PP_i formation or the rate of synthesis of labeled RNA were very similar. Product PP_i formed by as little as 0.6 unit of RNA polymerase in a 225-μl incubation medium could be measured.An automated version of the method was devised which allows accurate determination of PP_i down to 1 μm (without range expander attachment) at a sampling rate of 20–40 tubes/hr.     

Interaction of pyrophosphate with catalytic and noncatalytic sites of chloroplast ATP synthase

The effect of pyrophosphate (PP_i) on labeled nucleotide incorporation into noncatalytic sites of chloroplast ATP synthase was studied. In illuminated thylakoid membranes, PP_i competed with nucleotides for binding to noncatalytic sites. In the dark, PP_i was capable of tight binding to noncatalytic sites previously vacated by endogenous nucleotides, thereby preventing their subsequent interaction with ADP and ATP. The effect of PP_i on ATP hydrolysis kinetics was also elucidated. In the dark at micromolar ATP concentrations, PP_i inhibited ATPase activity of ATP synthase. Addition of PP_i to the reaction mixture at the step of preliminary illumination inhibited high initial activity of the enzyme, but stimulated its activity during prolonged incubation. These results indicate that the stimulating effect of PP_i light preincubation with thylakoid membranes on ATPase activity is caused by its binding to ATP synthase noncatalytic sites. The inhibition of ATP synthase results from competition between PP_i and ATP for binding to catalytic sites. Published in Russian in Biokhimiya, 2009, Vol. 74, No. 7, pp. 956–962.     

Dimethyl sulfoxide-induced hydroxyapatite formation: a biological model of matrix vesicle nucleation to screen inhibitors of mineralization

To elucidate the inhibition mechanisms of hydroxyapatite (HA), a biological model mimicking the mineralization process was developed. The addition of 4% (v/v) dimethyl sulfoxide (DMSO) in synthetic cartilage lymph (SCL) medium containing 2 mM calcium and 3.42 mM inorganic phosphate (P_i) at pH 7.6 and 37 °C produced HA as matrix vesicles (MVs) under physiological conditions. Such a model has the advantage of monitoring the HA nucleation process without interfering with other processes at the cellular or enzymatic level. Turbidity measurements allowed us to follow the process of nucleation, whereas infrared spectra and X-ray diffraction permitted us to identify HA. Mineral formation induced by DMSO and by MVs in the SCL medium produced crystalline HA in a similar manner. The nucleation model served to evaluate the inhibition effects of ATP, GTP, UTP, ADP, ADP-ribose, AMP, and pyrophosphate (PP_i). Here 10 μM PP_i, 100 μM nucleotide triphosphates (ATP, GTP, UTP), and 1 mM ADP inhibited HA formation directly, whereas 1 mM ADP-ribose and 1 mM AMP did not. This confirmed that the PP_i group is a potent inhibitor of HA formation. Increasing the PP_i concentration from 100 μM to 1 mM induced calcium pyrophosphate dihydrate. We propose that DMSO-induced HA formation could serve to screen putative inhibitors of mineral formation.     

STORAGE OF PHOSPHORUS IN NITROGEN-FIXING ANABAENA FLOS-AQUAE (CYANOPHYCEAE)1

P accumulation and metabolic pathway in N₂-fixing Anabaena flos-aquae (Lyngb.) Bréb were investigated in P-sufficient (20 μMP) and P-limited (2 μMP) turbidostats in combined N-free medium. The cyanobacterium grew at its maximum rate (μ_max, 1.13 d^?1) at the high P concentration and at 65% of μ_max under P limitation, with total cell P concentrations (Q_P) at steady states of 12.0 and 5.2 fmol·cell^?1, respectively. At steady state, polyphosphates (PP_i) accounted for only 3% of Q_P (0.4 fmol·cell^?1) in P-rich cells. Its concentration in P-limited cells was 5.8% (0.3 fmol·cell^?1). On the other hand, sugar P was very high at 22% of Q_P in P-rich cells and was undetectable in P-limited cells. Pulse chase experiments with ³²P showed that P-rich cells initially incorporated the labeled P into the acid-soluble PP_i fraction within the first few minutes and to a lesser extent into nucleotide P. Radioactivity in the PP_i then declined rapidly with concomitant increases in sugar P and nucleotide P fractions. In contrast, in P-limited cells, no radiolabel was detected in acid-soluble PP_i, and ³²P was initially incorporated into nucleotide P, sugar P, and ortho P fractions. The latter two fractions then subsequently declined. Therefore, under N₂-fixing conditions the cyanobacteria appeared to store P as sugar P and also utilize P through different pathways under P-rich and -limited conditions. When nitrate was supplied as the N source under P-sufficient conditions, PP_i accounted for about 15% of steady-state Q_P, but no sugar P was detected. Therefore, the same organism stored P in different cell P fractions depending on its N sources.     

Adenine nucleotide efflux in mitochondria induced by inorganic pyrophosphate

The efflux of mitochondrial adenine nucleotide which is induced by addition of PP_i to suspensions of rat liver mitochondria has been investigated. This efflux of adenine nucleotide is greatly stimulated by the uncoupler FCCP at 1 μM, V_max being 6.7 nmol/min per mg protein as compared to 2.0 nmol/min per mg protein in its absence. The depletion process is inhibited by carboxyatractyloside. The K_m for PP_i of 1.25 mM is essentially unchanged when uncoupler is added. Quantitation of the individual adenine nucleotide species (ATP, ADP and AMP) and their relationship to the rate of efflux suggests that ADP is the predominant species being exchanged for PP_i.     

Active creatine kinase is present in matrix vesicles isolated from femurs of chicken embryo: Implications for bone mineralization

Proteomic analysis of matrix vesicles (MVs) isolated from 17-day-old chicken embryo femurs revealed the presence of creatine kinase. In this report we identified the enzyme functionally and suggest that the enzyme may participate in the synthesis of ATP from ADP and phosphocreatine within the lumen of these organelles. Then, ATP is converted by nucleotide hydrolyzing enzymes such as Na⁺, K⁺-ATPase, protein kinase C, or alkaline phosphatase to yield inorganic phosphate (P_i), a substrate for mineralization. Alternatively, ATP can be hydrolyzed by a nucleoside triphosphate pyrophosphatase phosphodiesterase 1 producing inorganic pyrophosphate (PP_i), a mineralization inhibitor. In addition, immunochemical evidence indicated that VDAC 2 is present in MVs that may serve as a transporter of nucleotides from the extracellular matrix. We discussed the implications of ATP production and hydrolysis by MVs as regulatory mechanisms for mineralization.     

Studies on photosynthetic inorganic pyrophosphate formation in Rhodospirillum rubrum chromatophores

Photosynthetic formation of inorganic pyrophosphate (PP_i) in Rhodospirillum rubrum chromatophores has been studied utilizing a new and sensitive method for continuous monitoring of PP_i synthesis. Studies of the reaction kinetics under a variety of conditions, e.g., at different substrate concentrations and different electron-transport rates, have been performed. At very low light intensities the rate of PP_i synthesis is twice the rate of ATP synthesis. Antimycin A, at a concentration which strongly inhibited the photosynthetic ATP formation, inhibited the PP_i synthesis much less. Even at low rates of electron transport a significant rate of PP_i synthesis is obtained. The rate of photosynthetic ATP formation is stimulated up to 20% when PP_i synthesis is inhibited. It is shown that PP_i synthesis and ATP synthesis compete with each other. No inhibition of pyrophosphatase activity is observed at high carbonyl cyanide p-trifluoromethoxyhydrazone concentration while ATPase activity is strongly inhibited under the same conditions.     

Demonstration of ΔpH- and Δψ-induced synthesis of inorganic pyrophosphate in chromatophores from Rhodospirillum rubrum

It is possible to obtain synthesis of PP_i by artifical ion potentials in Rhodospirillum rubrum chromatophores. PP_i can be formed by K⁺-diffusion gradients (Δψ), H⁺ gradients (ΔpH) or a combination of both. In contrast, ATP can only be synthesized by imposed Δψ or Δψ+ΔpH. For ATP formation there is also a threshold value of K⁺ concentration below which synthesis of ATP is not possible. Such a threshold is not found for PP_i formation. Both PP_i and ATP syntheses are abolished by addition of FCCP or nigericin and only marginally affected by electron transport inhibitors. The synthesis of PP_i can be monitored for several minutes before it ceases, while ATP production stops within 30 s. As a result the maximal yield of PP_i is 200 nmol PP_i/μmol BChl, while that of ATP is no more than 25 nmol ATP/μmol BChl. The initial rates of syntheses were 0.50 μmol PP_i/μmol BChl per min and 2.0 μmol ATP/μmol per min, respectively. These rates are approx. 50 and 20% of the respective photophosphorylation rates under saturating illumination.     

Enzymatic Production of Pyrimidine Nucleotides Using Corynebacterium ammoniagenes Cells and Recombinant Escherichia coli Cells: Enzymatic Production of CDP-Choline from Orotic Acid and Choline Chloride (Part I)

Enzymatic production of cytidine diphosphate choline (CDP-choline) using orotic acid and choline chloride as substrates was investigated using a 200-ml beaker as a reaction vessel. When Corynebacterium ammoniagenes KY13505 cells were used as the enzyme source, UMP was accumulated up to 28.6 g/liter (77.6 mm) from orotic acid after 26 h of reaction. In this reaction, UDP and UTP were also accumulated, but CTP, a direct precursor of CDP-choline, was not accumulated sufficiently. Escherichia coli JF646/pMW6 cells, which overproduce CTP synthetase by selfcloning of the pyrG gene, were used together with cells of KY13505 for the enzymatic reaction using orotic acid as a substrate. CTP was produced at 8.95 g/liter (15.1 mm) after 23 h of this reaction. To produce CDP-choline, two additional enzyme activities were needed. E. coli MM294/pUCK3 and MM294/pCC41 cells, which express a choline kinase from Saccharomyces cerevisiae (CKIase; encoded by the CKI gene) and a cholinephosphate cytidylyltransferase from S. cerevisiae (CCTase; encoded by the CCT gene) respectively, were added to this CTP-producing reaction system. After 23 h of the reaction using orotic acid and choline chloride as substrates, 7.7 g/liter (15.1 mm) of CDP-choline was accumulated without addition of ATP or phosphoribosylpyrophosphate (PRPP). ATP and PRPP required in the CDP-choline forming reaction system are biosynthesized by those cells using glucose as a substrate.     

A method for the concentration and for the colorimetric determination of nanomoles of inorganic pyrophosphate

A generally applicable, inexpensive, and sensitive method for the determination of inorganic pyrophosphate (PP_i) was developed. PP_i was quantitatively separable from solution even in nanomolar concentrations by filtration through a membrane filter in the presence of CaCl₂ and KF. The separated PP_i was dissolved by immersing the filter in 0.5 n H₂SO₄. Inorganic phosphate (P_i) was removed by precipitating it as a phosphomolybdate-triethylamine complex and the PP_i was measured as a green pyrophosphomolybdate in the presence of 2-mercaptoethanol. Nucleotides and phosphate esters do not react. PP_i can be accurately assayed even when there is a 10⁴-fold excess of P_i. Trimetaphosphate, tripolyphosphate, and tetrapolyphosphate also give this green color, but the rate of the color formation is 50 times slower than that with PP_i. Thus this interference of the polyphosphates can be eliminated or the polyphosphates can be assayed simultaneously with the PP_i in the same sample.     

The interaction of myosine S1 with phosphorothioates of ADP: An 18O exchange study by 31P NMR

The ¹⁸O exchange reaction which labeled P_i undergoes in the presence of complexes of myosin subfragment 1, MgCl₂, and the different phosphorothioates of ADP has been observed by ³¹P NMR. From these experiments it can be concluded that ADP and ADP (α-S) (A) on the one hand and ADP (β-S) and ADP (α-S) (B) on the other hand form similar complexes as far as the number of reversals of the nucleoside triphosphate formation step from the nucleoside diphosphate and P_i, is concerned. In addition, the same seems to hold for the rate constant k_?2, which describes the binding step of free P_i, to the subfragment 1 nucleoside diphosphate complex. These observations support former kinetic experiments which yielded the same similarities for the rate parameters describing association and dissociation of the subfragment 1 nucleotide complexes.     

Inorganic pyrophosphate generation and disposition in pathophysiology

Inorganic pyrophosphate (PP_i)regulates certain intracellular functions and extracellular crystaldeposition. PP_i is produced, degraded, and transported byspecialized mechanisms. Moreover, dysregulated cellular PP_iproduction, degradation, and transport all have been associated withdisease, and PP_i appears to directly mediate specificdisease manifestations. In addition, natural and synthetic analogs ofPP_i are in use or currently under evaluation asprophylactic agents or therapies for disease. This review summarizes recent developments in the understanding of how PP_i is madeand disposed of by cells and assesses the body of evidence forpotentially significant physiological functions of intracellularPP_i in higher organisms. Major topics addressed are recentlines of molecular evidence that directly link decreased and increasedextracellular PP_i levels with diseases in which connectivetissue matrix calcification is disordered. To illustrate in depth theeffects of disordered PP_i metabolism, this review weighsthe roles in matrix calcification of the transmembrane protein ANK,which regulates intracellular to extracellular movement ofPP_i, and the PP_i-generating phosphodiesterase nucleotide pyrophosphatase family isoenzyme plasma cell membrane glycoprotein-1 (PC-1).

     

Diphosphate concentration does not correlate with the level of inorganic diphosphatase inEscherichia coli

Partial inhibition of DNA synthesis stimulates the production of inorganic diphosphatase inEscherichia coli but the changes in diphosphate (PP _i) level observed did not correlate with the enzyme activity. An accumulation ofPP _I was observed in the presence of inhibitors of RNA synthesis or nucleotide synthesis. In the former case the level of the enzyme did not change but in the latter case it increased. Thus the amount of inorganic diphosphatase alone does not determine the concentration ofPP ₁ inE. coli.     

Transcription of polyoma virus DNA after interaction with nuclear proteins in vitro.

Analysis of the nucleotide sequence at the 5′-triphosphate termini of RNA chains synthesized by T7 RNA polymerase from T7 DNA template indicates that nearly all RNA chains synthesized in this polymerase reaction contain the sequence, pppGpGp. In addition, studies carried out on T7 DNA-dependent ³²PP_i exchange into ribonucleoside triphosphates suggest that immediately following the guanine residues at the 5′-end of RNA formed in the T7 RNA polymerase reaction, there is one or more adenine residues. These results indicate a high degree of specificity of initiation of RNA synthesis by T7 RNA polymerase.     

LUXURY PHOSPHATE UPTAKE AND VARIATION OF INTRACELLULAR METAL CONCENTRATIONS IN HETEROSIGMA AKASHIWO (RAPHIDOPHYCEAE)1

The effectr of phosphate starvation and subsequent uptake on distribution and concentration of phosphate metabolic intermediates and metals were studied in Heterosigma akashiwo (Hada) Hada by ³¹P-NMR spectroscopy, neutron activation analysis and ESR spectroscopy. Excess orthophosphate (4.5 μM P_i, as NaH₂PO₄) added to a medium with P-depleted H. akashiwo cells was rapidly taken up resulting in an increase in P cell quota (q_p)from 68.2 to 99.6 fmol. cell-¹in 2 h and to 156.3 fmol. cell-¹in 6 h. After three days, q_p approached about 190 fmol. cell^?1. Polyphosphate (PP_i) rapidly increased from 0 to 11.4 fmol· cell^?1in 2 h and to 24.7 fmol·cell^?1in 6 h. Diel variation of cell quota indicated that cellular P_i increase was synchronized with cellular PP_i decrease and vice versa. The average chain length of PP_i increased from ca. 0 to ca. 10.2 phosphate residues in 2 h after addition of P_i and one day later, from ca. 9.8 to ca. 12.5. The cell quota of Mn (q_Mn), and to a lesser extent Co, increased rapidly from 4.87 fg. cell^?1in the P- starved condition to 50.48 fg·cell^?12 h afer addition of P_i but decreased to 8.63 fg. Cell^?1by 6 h. Concentrations of Zn, As, Hf, Cu and sometimes Al, Mg, K, and Ca changed in a manner opposite to that of Mn and Co. The excretion of these cations, which was synchronized with the uptake of Mn and Co, may be important for a charge balancing in the cells. The ESR spectra showed that the high cellular Mn observed at 2 h after P addition was Mn²⁺which was taken up by the cells rather than adsorbed on the cell surface. These data combined with PP_i data suggested that the behavior of q_Mn is synchronized with the behavior of average chain length of PP_i.     

Acid Gradient across Plasma Membrane Can Drive Phosphate Bond Synthesis in Cancer Cells: Acidic Tumor Milieu as a Potential Energy Source

Aggressive cancers exhibit an efficient conversion of high amounts of glucose to lactate accompanied by acid secretion, a phenomenon popularly known as the Warburg effect. The acidic microenvironment and the alkaline cytosol create a proton-gradient (acid gradient) across the plasma membrane that represents proton-motive energy. Increasing experimental data from physiological relevant models suggest that acid gradient stimulates tumor proliferation, and can also support its energy needs. However, direct biochemical evidence linking extracellular acid gradient to generation of intracellular ATP are missing. In this work, we demonstrate that cancer cells can synthesize significant amounts of phosphate-bonds from phosphate in response to acid gradient across plasma membrane. The noted phenomenon exists in absence of glycolysis and mitochondrial ATP synthesis, and is unique to cancer. Biochemical assays using viable cancer cells, and purified plasma membrane vesicles utilizing radioactive phosphate, confirmed phosphate-bond synthesis from free phosphate (P_i), and also localization of this activity to the plasma membrane. In addition to ATP, predominant formation of pyrophosphate (PP_i) from P_i was also observed when plasma membrane vesicles from cancer cells were subjected to trans-membrane acid gradient. Cancer cytosols were found capable of converting PP_i to ATP, and also stimulate ATP synthesis from P_i from the vesicles. Acid gradient created through glucose metabolism by cancer cells, as observed in tumors, also proved critical for phosphate-bond synthesis. In brief, these observations reveal a role of acidic tumor milieu as a potential energy source and may offer a novel therapeutic target.